Quantitative quasi-invariance of Gaussian measures below the energy level for the 1D generalized nonlinear Schr\"odinger equation and application to global well-posedness

Abstract

We consider the Schr\"odinger equation on the one dimensional torus with a general odd-power nonlinearity p ≥ 5, which is known to be globally well-posed in the Sobolev space Hσ(T), for every σ ≥ 1, thanks to the conservation and finiteness of the energy. For regularities σ < 1, where this energy is infinite, we explore a globalization argument adapted to random initial data distributed according to the Gaussian measures μs, with covariance operator (1-)s, for s in a range (sp,32]. We combine a deterministic local Cauchy theory with the quasi-invariance of Gaussian measures μs, with additional Lq-bounds on the Radon-Nikodym derivatives, to prove that the Gaussian initial data generate almost surely global solutions. These Lq-bounds are obtained with respect to Gaussian measures accompanied by a cutoff on a renormalization of the energy; the main tools to prove them are the Bou\'e-Dupuis variational formula and a Poincar\'e-Dulac normal form reduction. This approach is similar in spirit to Bourgain's invariant argument and to a recent work by Forlano-Tolomeo.